EP4320670A1 - Connecting unit for electrically contacting at least two storage cells, storage unit, and method - Google Patents

Abstract

The invention relates to a connection unit (10, 10', 20, 20', 30, 30') for electrically contacting at least two storage cells (42-50') for storing electric energy, to a first storage unit, and to a second storage unit for storing electric energy, and to a method for producing a first storage unit and a second storage unit. In particular, the invention relates to a connection unit (10, 10', 20, 20', 30, 30') for electrically contacting at least two storage cells (42-50') for storing electric energy, comprising a current-conducting connection body (12, 22, 32) and at least two contact sections (14, 24, 34) which are designed to connect to the storage cells (42-50'), wherein at least one of the two contact sections (14, 24, 34) has a predetermined breaking point (16, 26, 36) and/or the connection unit (10, 10', 20, 20', 30, 30') comprises at least one opening section (28, 38, 39) which is arranged and designed such that at least a part of a contact section remaining on a storage cell (42-50') can protrude into the opening section (28, 38, 39).

Description

Connection unit for electrically contacting at least two storage cells, storage unit and method

The invention relates to a connection unit for electrically contacting at least two storage cells for storing electrical energy, a first storage unit and a second storage unit for storing electrical energy, and a method for producing a first storage unit and a second storage unit.

Connection units for electrically contacting at least two storage cells are known in principle. Such connection units are also known as current collectors or busbars. Storage units, for example accumulators or batteries for electrically operated motor vehicles, usually include a large number of storage cells which are connected to connection units. The storage cells can be battery cells, for example. A storage unit designed as a battery is, for example, an electrochemical energy store.

During the service life of such a storage unit, defects or wear occur or usually occur in several of the storage cells, so that their efficiency is reduced. These memory cells reduce the performance of the memory device.

Memory units can be refurbished by replacing defective memory cells. A defect can also be understood as wear that reduces the performance of the storage cell. These memory cells are exchanged, among other things, by removing at least one connection unit from the memory unit. However, removing the connection unit often results in damage to the storage unit. Because of this, the connection units are usually removed from the individual memory cells with a great deal of technical effort, so that these remain intact even after the connection unit has been removed.

For most applications of memory units processed in this way, however, the above-mentioned effort does not make sense for economic reasons. For this reason, storage units with storage cells, which at least partially have a reduced performance, are often used for what is known as a second life cycle, in particular as a power storage device. However, these power storage devices have a low level of performance, since the number of defective storage cells continues to increase over the period of use. Such electricity storage devices are used, for example, as stationary electrical energy storage devices.

It is preferred that such memory units can also deliver a comparatively high electrical power and thus the performance of such memory units is also increased in the second life cycle. In addition, the recycling process must be designed efficiently, since otherwise no economic use is possible in the second life cycle.

It is therefore an object of the invention to provide a connection unit for making electrical contact between at least two storage cells for storing electrical energy, a first storage unit and a second storage unit for storing electrical energy, and methods for producing a first storage unit and a second storage unit, which have one or more reduce or eliminate the disadvantages mentioned. It is particular It is an object of the invention to provide a solution that improves the processing of a storage unit for storing electrical energy.

According to a first aspect, this object is achieved by a

Connection unit for making electrical contact with at least two storage cells for storing electrical energy, comprising a current-conducting connection body, at least two contact sections which are designed for connection to the storage cells, wherein at least one of the two contact sections has a predetermined breaking point and/or wherein the

Connection unit comprises at least one opening section, which is arranged and configured such that at least part of a contact section remaining on a memory cell can protrude into the opening section.

The connection of two storage cells by means of the connection unit described above can be released in an advantageous manner by removing the connection unit from the storage cells in such a way that the connection unit breaks at the predetermined breaking point(s) and a part of the connection unit thus remains on the storage cells. The inventors have surprisingly found that parts of the connection unit can remain on the memory cells without the production of a memory unit for the second life cycle being made significantly more difficult. The invention was also based on the finding that the opinion, which has long been prevalent in the industry, that the connection unit should be completely removed from the memory cells, is not correct, since the remaining contact section can be arranged in the opening section or a contact section of a connection unit in the second Life cycle can be welded to the remaining contact portion.

The connection unit for making electrical contact with at least two storage cells is designed in particular in such a way that an electric current can flow from a first storage cell to a second storage cell when the connection unit is arranged as intended. For this purpose, the connection unit has, in particular, an electrically conductive material.

The connection unit comprises the electrically conductive connection body, the at least two contact sections and at least one predetermined breaking point on one the contact sections and/or the at least one opening section. The connection body and the contact sections can be formed in one piece. In addition, the connecting body and the contact sections can be connected to one another in a materially bonded manner. In addition, the connecting body and the contact sections can also be separate components that are electrically conductively connected to one another.

The contact sections are designed in such a way that they can be electrically connected to storage cells for storing electrical energy. The contact sections are preferably designed in such a way that a connection of the contact section to the storage cells can be welded and/or soldered.

The connection unit preferably has a plurality of contact sections which are arranged adjacent to one another. It is particularly preferred that the contact portions are arranged in a row. Lead portions of these memory cells are also arranged adjacent to each other. The connection unit has guide sections corresponding to such

Contact sections, so that the contact sections can be brought into connection with the conducting sections of the memory cells. Two, several or all contact sections preferably have a predetermined breaking point.

The contact portions of the connection unit may, for example, have a contact portion area of less than, equal to or more than 1 mm ² , more than 5 mm ² , more than 10 mm ² , more than 15 mm ² , more than 25 mm ² , more than 100 mm ² , more than 500 mm ² , more than 1000 mm ² and/or more than 2000 mm ² .

The contact sections are preferably arranged and designed such that welding can take place through them and a current-conducting connection can be formed by welding to an adjacent storage cell.

When the connection unit is removed from a memory unit, at least parts of the contact sections remain on the memory cells. These contact sections are referred to below as remaining contact sections. If these memory cells are again contacted with a connection unit, at least parts of the contact sections are located between the memory cells and the connection unit. Since the remaining If contact sections are applied at different heights, their distal ends are usually not in a connection plane. The connection unit can rest, for example, on three or four contact sections remaining on the storage cells. The further storage cells and/or contact sections can be spaced apart from the connection unit, so that contacting, for example using a welding process, is made more difficult.

The connection unit with the opening section solves this problem in that the distances between the connection unit and the memory cells are not influenced by the remaining contact sections, in that they protrude into the opening section. The connection unit can thus be arranged essentially planarly on the memory cells, independently of the remaining contact sections.

The opening section can also be referred to as a free space. The opening section can be an opening enclosed on all sides. Alternatively, the opening can have one, two or more open sides. Such an opening section has in particular a concave side, for example an opening. The geometry of the opening section preferably essentially corresponds to the geometry of the contact sections and/or the predetermined breaking point. The opening section preferably has larger dimensions than the contact sections. In particular, it is preferred that a loose fit can be formed between the opening section and the contact section. The contact sections are preferably arranged adjacent to one another in a first row and two or more opening sections are arranged adjacent to one another in a second row, so that one contact section and one opening section are preferably arranged next to one another. Such an arrangement is also referred to as a paired arrangement of the contact sections and the opening sections.

It is further preferred that the connection unit has a first number of contact sections and a second number of opening sections, the first number corresponding to the second number. In addition, it is preferred that the contact portions in a first arrangement pattern and the opening portions in a second arrangement pattern on the Connecting bodies are arranged, preferably wherein the first arrangement pattern corresponds to the second arrangement pattern. The first and/or second arrangement pattern can be configured in a row and/or in a zigzag shape, for example. In a preferred embodiment variant of the connection unit, it is provided that the predetermined breaking point is designed in such a way that when the connection unit is removed from the at least two storage cells, at least the contact section with the predetermined breaking point is at least partially separated from the connection body and preferably remains on the storage cell. Substantially separate from the connecting body means in particular that the contact section remains at least partially or completely on the storage cell.

In a further preferred embodiment variant of the connection unit, it is provided that the predetermined breaking point is designed in such a way that a predefined notch effect occurs when the connection unit is removed. Usually, the connection unit is mechanically removed from the storage cells from a first end or from a second end by the application of force. Based on this, a notch effect can be predefined by designing the predetermined breaking point accordingly. A notch effect is defined in particular as a local stress concentration. For example, the predetermined breaking point can have a notch or be designed as a notch, with the notch bringing about the notch effect.

A further preferred embodiment of the connection unit is characterized in that the predetermined breaking point has a lower material thickness than the at least two contact sections and/or the connection body. It is preferred that the predetermined breaking point or predetermined breaking points and the at least two contact sections each have the same material thickness and the connecting body has a greater material thickness. Such a material thickness gradient can form a predetermined breaking point. A further preferred variant of the connection unit provides that the predetermined breaking point is designed as a laterally open slot. The laterally open slot preferably extends from a lateral edge of the Connecting body to the corresponding contact portion, so that a notch effect occurs when removing the connection unit.

It is preferred that a ratio of the material thickness of the predetermined breaking point and a material thickness of the connecting body is less than 0.8, less than 0.6, less than 0.4 and/or less than 0.2. In the case of a connection unit designed in this way, the predetermined breaking point is formed, among other things, by a step that is formed by the two different material thicknesses. The material thickness of the predetermined breaking point can be made smaller than the material thickness of the connecting body and/or the contact sections, for example by removing material. The connection unit can be produced, for example, in such a way that material is removed on the connection body for each predetermined breaking point around a contact section assigned to the predetermined breaking point.

A further preferred development of the connection unit is characterized in that the predetermined breaking point is designed as a weak point in the material. The weak point in the material can be formed, for example, by a mechanical and/or chemical weakening of the material of the predetermined breaking point.

A further preferred embodiment variant of the connection unit is characterized in that the at least two contact sections and/or the connection body have a first material and the predetermined breaking point has a second material, the first material being different from the second material.

It is particularly preferred that the predetermined breaking point and the contact sections have the second material and the connecting body has the first material. In addition, it is preferred that the contact sections and the connecting body have different materials. One, two or more different properties of the first and of the second material can make it possible for the first material to be different from the second material. For example, the first material can have a greater hardness than the second material. According to a further preferred embodiment variant of the connection unit, it is provided that the predetermined breaking point has one, two or more openings, the opening or the two or more openings preferably being designed as a notch or notches and/or as a perforation or perforations. In addition, the predetermined breaking point can have a scratch mark or be designed as a scratch mark. Alternatively or additionally, it is preferred that the predetermined breaking point is designed as one, two or more openings, with the opening or openings preferably being designed as a notch or notches and/or as a perforation or perforations. The opening can be designed as a blind hole or as a through opening. It is also preferred that the predetermined breaking point has the opening or openings mentioned above and also has the different materials and/or different material thicknesses described above. It is particularly preferred that the at least one opening section has a recess or is designed as a recess. The recess can be designed in the form of a slot, for example. The recess or recesses is or are preferably designed as a through-opening or as through-openings. It is particularly preferred that the at least two contact sections and the at least one opening section are dimensioned such that one of the contact sections can be arranged within the at least one opening section.

According to a further aspect, the object mentioned at the outset is achieved by a first storage unit for storing electrical energy, in particular for an electrically driven vehicle and/or a power storage device, comprising at least two storage cells, a first connection unit according to one of the aforementioned embodiment variants, the at least two memory cells are electrically connected by means of the first connection unit.

The electrical connection between the at least two storage cells is formed in particular in that one storage cell is electrically connected to a contact section and the contact sections are also electrically connected by means of the current-conducting connecting body. the Memory cells preferably have conductive sections, with a conductive section in each case being connected to a contact section of the connection unit. The conductive sections can be formed by poles of the memory cells, for example, or can be poles of the memory cells. It is particularly preferred that the first memory unit has a multiplicity of memory cells and the first connection unit has a number of contact sections that corresponds to the number of memory cells, so that a contact section can preferably be arranged on each conducting section.

It is preferred that the first storage unit is included as an electrical energy store of an electrically operated vehicle for providing drive energy. In addition, the first storage unit can be comprised by a charging device for electrically operated vehicles or by a stationary storage unit.

According to a further aspect, the object mentioned at the outset is achieved by a second storage unit for storing electrical energy, in particular for a power storage device, comprising at least two storage cells, with at least one of the storage cells having a remaining contact section of a first connection unit, a second connection unit, in particular according to one of the The embodiment variants described above, in which an opening section of the second connection unit is arranged in such a way that the remaining contact section projects into the opening section, and/or in which a contact section of the second connection unit is connected to the remaining contact section, preferably in a materially bonded manner, in particular by welding, and in which the at least two memory cells are electrically connected by means of the second connection unit.

The second connection unit preferably comprises a current-conducting connection body, at least two contact sections which are designed for connection to the storage cells, with at least one of the two contact sections having a predetermined breaking point and/or with the connection unit comprising at least one opening section which is arranged and designed such that at least part of the contact portion remaining on the memory cell may protrude into the opening portion. The second storage unit is preferably based on the first storage unit. The at least two memory cells of the second memory unit can, for example, be memory cells that were already contained in a first memory unit. Furthermore, one, two or more memory cells with reduced performance of the first memory unit can be replaced by more powerful memory cells. The fact that one of the memory cells has a contact section of a first connection unit may be due to the fact that these memory cells were connected to one another with a first connection unit and the connection unit was removed from the memory cells in such a way that when the connection unit was removed from the at least two memory cells, the contact sections in the have been substantially separated from the connecting body and have remained on the memory cells.

A memory unit designed in this way can be advantageously manufactured. In particular, the possibility of arranging and contacting the second connection unit essentially flat on the memory cells reduces the manufacturing outlay.

The fact that at least one of the memory cells has a contact section of a first connection unit means in particular that at least one of the memory cells has at least part of the contact section of the first connection unit.

It is preferred that the second storage unit is comprised by a charging device for electrically operated vehicles.

The second storage unit can also be a third, fourth or further storage unit, wherein at least one of the storage cells has two, three or more remaining contact sections of first, second and/or further connection units, which has a third, fourth or further connection unit, in particular after one of the embodiment variants described above, wherein opening sections are arranged on the remaining contact sections in such a way that the remaining contact sections protrude into the opening sections, and/or wherein contact sections of the third, fourth or further connection unit are materially bonded to one or more of the remaining contact sections, in particular are connected by welding, and wherein the at least two storage cells are electrically connected by means of the third, fourth or further connection unit.

According to a further aspect, the object mentioned at the outset is achieved by a method for producing a first storage unit, in particular a first storage unit according to one of the embodiment variants described above, comprising the steps: providing at least two storage cells for storing electrical energy and a first connection unit for electrical Contacting of the at least two storage cells, in particular a connection unit according to one of the aforementioned embodiment variants, and electrically connecting the two storage cells to the first connection unit.

The first connection unit has a current-conducting connection body and at least two contact sections, which are designed for connection to the storage cells. Furthermore, at least one of the contact sections has a predetermined breaking point.

The electrical connection can take place, for example, by means of welding, in particular laser welding, or soldering.

According to a further aspect, the object mentioned at the beginning is achieved by a method for producing a second memory unit, in particular a second memory unit according to one of the embodiment variants described above, comprising the steps: providing a first memory unit, in particular a first memory unit according to one of the variants described above design variants; Removing the first connection unit in such a way that at least one of the contact sections of the first connection unit remains at least partially on one of the storage cells, the at least one remaining contact section preferably being separated from the connection body at the predetermined breaking point; Contacting the memory cells by means of a second connection unit, in particular a connection unit according to one of the embodiment variants described above, having at least two contact sections which are designed for connection to the memory cells; where the remaining Contact section protrudes into the opening section and/or wherein at least one of the contact sections of the second connection unit is connected to the remaining contact section, preferably materially, in particular by welding. The method described above can also be used to produce a third, fourth or further memory unit, in which case the opening section can also have two or more recesses for receiving a plurality of contact sections per memory cell.

In a preferred embodiment variant, the method includes the step: replacing one, two or more of the memory cells of the first memory unit. In particular, the one, two or more memory cells are replaced by memory cells with a higher performance. The memory cells to be exchanged preferably have a reduced performance. It is therefore further preferred that the method comprises the step: detecting memory cells with a reduced performance. Reduced performance is characterized in particular by a drop in performance compared to full performance of more than 20%, more than 30%, more than 40% and/or more than 50%. The manufactured second memory unit preferably comprises memory cells already contained in the first memory unit and additional memory cells which replace memory cells with a low performance of the first memory unit.

The methods and their possible developments have features or method steps that make them particularly suitable for being used for a connection unit, a first memory unit and/or a second memory unit.

For further advantages, design variants and design details of the further aspects and their possible developments, reference is also made to the previously given description of the corresponding features and developments of the connection unit. Preferred embodiments are exemplified by the enclosed

Figures explained. Show it:

FIG. 1: schematic views of exemplary embodiments of connection units; FIG. 2 shows a schematic view of an exemplary embodiment of adjacently arranged memory cells;

FIG. 3: a schematic view of an exemplary embodiment of a first memory unit;

FIG. 4: a schematic view of the first memory unit shown in FIG. 3 with removed first connection units;

FIG. 5 shows a schematic view of an exemplary embodiment of a second memory unit;

FIG. 6: a schematic view of the second one shown in FIG

storage unit with removed second connection units; FIG. 7: a schematic view of an exemplary embodiment of a third memory unit;

FIG. 8: a schematic first method;

FIG. 9: a schematic second method; and

FIG. 10: a schematic third method. In the figures, identical or essentially functionally identical or similar elements are denoted by the same reference symbols.

FIG. 1 shows a first connection unit 10. The first connection unit 10 comprises a connection body 12 and five contact sections 14, of which only one contact section is provided with the reference number 14. The contact sections 14 each have a predetermined breaking point 16 . The predetermined breaking point 16 can, for example, enclose the contact section 14 so that the geometry of the predetermined breaking point 16 is designed as a square. the Predetermined breaking points 16 can be formed, for example, in each case as a perforation on the outer circumference of the contact sections 14 . In addition, the predetermined breaking point 16 and/or the contact section 14 can have a smaller material thickness than the connecting body 12 and/or a different material than the connecting body 12 .

FIG. 1 also shows a second connection unit 20 with a connection body 22. The second connection unit 20 has five second contact sections 24. FIG. The second contact sections 24 each include a predetermined breaking point 26 . The second connection unit 20 also has five opening sections 28 . The opening sections 28 and the second contact sections 24 are each arranged in pairs, so that an opening section 28 is arranged next to each second contact section 24 . The opening portions 28 are arranged substantially at the position where the contact portions 14 are arranged on the first connection unit 10 . By means of such an arrangement, a memory unit which is improved in relation to a used memory unit can be provided by means of the second connection unit 20 . In the event that the first connection unit 10 is removed from the storage cells of a storage unit, the contact sections 14 are removed from the connection body 12 by means of the predetermined breaking points 16 at least in sections, ie partially. The contact sections 14 remain at least in sections on the storage cells. If the second connection unit 20 is arranged on these storage cells, the remaining contact sections 14 can protrude into the opening sections 28, so that the second connection unit 20 can be arranged essentially flat on the storage cells.

Alternatively, a further first connection unit 10, 10 ^' can be arranged on the storage cells and the first contact sections 14 are welded to the remaining contact sections and/or the storage cells. In addition, a third connection unit 30 is shown in FIG. 1, which can be used for a third life cycle of a memory unit. The third connection unit also has a connection body 32, third Contact sections 34 and predetermined breaking points 36 respectively. The third connection unit also has two opening sections 38, 39 which are each arranged next to a third contact section 34.

As soon as the second connection unit 20 is removed from a memory unit, the second contact sections 24 remain analogous to the first connection unit 10 on the memory cells. The opening sections 38, 39 of the third connection unit 30 thus make it possible for the third connection unit to be arranged evenly on the memory cells and for it to be brought into contact with conductive sections of the memory cells, so that contacting of the memory cells with the third connection unit is advantageously made possible.

FIG. 2 shows five memory cells 42-50 arranged one above the other. Each of the memory cells 42-50 comprises two lead sections 52-60, only one of the lead sections 52-60 of a memory cell being provided with a reference number. FIG. 3 shows a memory unit 40 which has the memory cells 42-50 shown in FIG. 2 and two first connection units 10, 10'. The storage cells 42-50 are electrically connected by means of the first connection units 10, 10'. For this purpose, the connection units 10, 10' are positioned in such a way that a contact section 14 is arranged in one of the conducting sections 52-60. A permanent connection can, for example, by welding the

Contact portions 14 with the conductive portions 52 - 60 are formed. Such a memory unit 40 can be used in an electrically operated vehicle, for example.

Figure 4 shows the storage unit 40 previously shown, with the first connection units 10, 10' removed. It can be seen that the

Contact sections 14 on the conductive sections 52 - 60 are left. The first connection units 10, 10 'are, for example, by mechanical

Force has been removed, with the predetermined breaking points 16 of the contact sections 14, the contact sections 14 on the conducting sections 52 - 60 remained. Figure 5 shows a second memory unit 40' wherein the memory cell 50 has been replaced with a higher performance memory cell 50' having two lead sections 60' since the memory cell 50 had a reduced performance. The storage cells 42-50' are electrically connected to one another with second connection units 20, 20'. It can be seen that opening sections

28 of the connecting units 20, 20' are arranged where the

Contact sections 14 are left. The contact sections 14 can basically be seen through the opening sections 28 . For better understanding, this detail has not been shown. The memory cells 42 - 50' are each connected to the second contact sections 24 at their lead sections 52 - 60'. Such a second storage unit 40' can be used, for example, as a power storage device, in particular in a charging device, for example a charging station, for electric vehicles.

FIG. 6 shows the second storage unit 40′, the connection units 20, 20′ having been removed and analogous to the first storage unit 40 only the second ones

Contact sections 24 and the contact sections 14 are arranged on the conducting sections 52-60'.

FIG. 7 shows a third storage unit 40″ on which two third connection units 30, 30′ are arranged. The contact sections 14, 24 remaining on the storage cells 42-50' protrude into the opening sections 38, 39 of the connecting body 32. The connection units 30, 30' electrically connect the memory cells 42 - 50' by means of the third contact portions 34 and the connection body 32. The third contact portions 34 of the third

In addition, connection units 30, 30' each have a predetermined breaking point 36. The third contact portions 34 can alternatively without the

be designed as a predetermined breaking point, in particular if removal of the third connection units 30, 30' is not intended. This can apply analogously to the second connection units 20, 20' if the second

Connection units 20, 20' are not to be removed from the memory cells. The storage units 40, 40′, 40″ shown above enable power storage devices that can be produced in a particularly advantageous manner and that are powerful and that can be used in a wide variety of applications. In particular, will In contrast to the prior art, a third life cycle of an electricity storage device is made possible, which could not be produced economically from the previously known point of view.

FIG. 8 shows a schematic method for producing a first memory unit. In step 100, at least two storage cells 42-50 for storing electrical energy and a first connection unit 10, 10' for electrically contacting the at least two storage cells 42-50 are provided. In step 102, the at least two storage cells 42-50 are connected to the first connection unit 10, 10'. FIG. 9 shows a method for producing a second memory unit 40'. In step 200 a first storage unit 40 is provided. In step 202, the first connection unit 10, 10' is removed in such a way that at least one of the contact sections 14 of the first connection unit 10, 10' remains at least partially on one of the storage cells 42 - 50, the at least one contact section 14 being separated from the connection body 12 on the Breaking point 16 is separated.

In step 204, the storage cells 42-50 are contacted by means of a second connection unit 20, 20'. The second connection unit 20, 20' has second contact sections 24 which are designed for connection to the memory cells 42-50.

The storage cells 42 - 50 are contacted in such a way that at least one opening section 28 of the second connection unit 20, 20' acts on the at least one contact section 14 in such a way that at least part of a contact section 14 remaining on a storage cell 42 - 50 protrudes into the opening section 28 can.

Alternatively, the contact can be made by a material connection of the second contact sections 24 of the connection unit 20, 20' with the remaining first contact sections 14.

Step 202 may further include the sub-step of swapping one, two, or more of the memory cells 42-50, for example by a spare memory cell 50'. Thus, the performance of the second memory unit 40' is increased.

FIG. 10 shows a method for producing a storage unit 40″ in a further life cycle, which could be the third or fourth life cycle, for example. In step 300, a second storage unit 40' is provided. In step 302, the second connection units 20, 20' are removed in such a way that at least one of the second contact sections 24 of the second connection units 20, 20' remains at least partially on one of the storage cells 42-50', with the at least one second contact section 24 preferably being separated from the Connecting body 22 is separated at the predetermined breaking point 26. In step 304, the memory cells 42-50' are contacted by means of a third connection unit 30, 30'.

Contacting takes place in particular in such a way that at least a first opening section 38 of the third connection unit 30, 30' on the at least one contact section 14 and a second opening section 39 of the third connection unit 30, 30' on the at least one second contact section 24 act in such a way that the remaining Contact sections 14, 24 protrude into the opening sections 38, 39.

With the methods described above, storage units 40, 40', 40'' can be recycled or reused particularly efficiently. In particular, the removal of the connection units 10, 10', 20, 20', 30, 30' is possible with little effort, since the predetermined breaking points 16, 26, 36 mean that parts of the connection units 10, 10', 20, 20', 30 , 30' at the storage cells 42-50'. Furthermore, the storage units 40′, 40″ can be produced particularly advantageously, since remaining contact sections 14, 24 do not have to be removed and no spacings between storage cells 42-50′ and connection units 20, 20′, 30, 30′ have to be bridged when making contact . REFERENCE MARKS

10, 10' first connection unit

12 connecting body 14 contact portion

16 breaking point

20, 20' second connection unit

22 connecting body

24 second contact section 26 predetermined breaking point 28 opening section

30, 30' third connection unit

32 connecting body

34 third contact section 36 predetermined breaking point

38 opening section

39 opening section

40, 40', 40" memory unit 42 memory cell 44 memory cell

46 memory cell 48 memory cell

50, 50' storage cell

52 Lead Section Leading Section Leading Section Leading Section Leading Section

Claims

EXPECTATIONS

1. Connection unit (10, 10', 20, 20', 30, 30') for electrically contacting at least two storage cells (42-50') for storing electrical energy, comprising - a current-conducting connection body (12, 22, 32), at least two contact sections (14, 24, 34) which are designed for connection to the storage cells (42-50'), wherein at least one of the two contact sections (14, 24, 34) has a predetermined breaking point (16, 26, 36) and /or wherein the connecting unit (10, 10', 20, 20', 30, 30') comprises at least one

Opening section (28, 38, 39) which is arranged and designed such that at least a part of a contact section remaining on a storage cell (42-50') can protrude into the opening section (28, 38, 39).

2. Connection unit (10, 10', 20, 20', 30, 30') according to claim 1, wherein the predetermined breaking point (16, 26, 36) is designed such that when removing the connection unit (10, 10', 20, 20', 30, 30') from the at least two storage cells (42-50'), at least the contact section with the predetermined breaking point (16, 26, 36) at least partially from the connecting body

(12, 22, 32) and preferably remains on the storage cell (42-50').

3. Connection unit (10, 10', 20, 20', 30, 30') according to one of the preceding claims, wherein the predetermined breaking point (16, 26, 36) is designed such that when removing the connection unit (10, 10', 20, 20', 30, 30') a predefined notch effect occurs.

4. Connection unit (10, 10', 20, 20', 30, 30') according to any one of the preceding claims, wherein the predetermined breaking point (16, 26, 36) has a smaller Has material thickness than the at least two contact sections (14, 24, 34) and / or the connecting body (12, 22, 32).

5. Connection unit (10, 10', 20, 20', 30, 30') according to one of the preceding claims, wherein the at least two contact sections (14, 24, 34) and/or the connection body (12, 22, 32) a first material, and the predetermined breaking point (16, 26, 36) have a second material, the first material being different from the second material.

6. Connection unit (10, 10 ', 20, 20', 30, 30 ') according to any one of the preceding claims, wherein the predetermined breaking point (16, 26, 36) has one, two or more openings, wherein preferably the opening or the two or more openings as a notch or notches and/or as a perforation or

Perforations is formed or are.

7. Connection unit (10, 10′, 20, 20′, 30, 30′) according to one of the preceding claims, wherein the at least one opening section (28, 38, 39) has a recess or is designed as a recess, in particular as a through opening is trained.

8. Connection unit (10, 10 ', 20, 20', 30, 30 ') according to any one of the preceding claims, wherein the at least two contact sections (14, 24, 34) and the at least one opening section (28, 38, 39) such are dimensioned such that one of the contact sections (14, 24, 34) can be arranged within the at least one opening section (28, 38, 39).

9. First storage unit (40) for storing electrical energy, in particular for an electrically powered vehicle and/or a power storage device, comprising at least two storage cells (42-50'), - a first connection unit (10, 10', 20, 20', 30, 30') according to one of the preceding claims 1-8, wherein the at least two storage cells (42-50') are electrically connected by means of the first connection unit (10, 10', 20, 20', 30, 30'). 10. Second storage unit (40', 40") for storing electrical energy, in particular for a power storage device, comprising at least two storage cells (42-50'), wherein at least one of the storage cells (42-50') has a remaining contact section of a first connection unit ( 10, 10', 20, 20', 30, 30'), - a second connection unit (10, 10', 20, 20', 30, 30'), in particular according to one of the preceding claims 1-8, wherein a Opening section (28, 38, 39) of the second connection unit is arranged in such a way that the remaining contact section projects into the opening section (28, 38, 39), and/or wherein a contact section (14, 24, 34) of the second connection unit (10, 10',

20, 20', 30, 30') is connected to the remaining contact section (14, 24, 34), preferably cohesively, in particular by welding, and wherein the at least two storage cells (42-50') are connected by means of the second connection unit (10,

10', 20, 20', 30, 30') are electrically connected.

11. A method for producing a first memory unit (40), in particular a first memory unit according to claim 9, comprising the steps:

Providing at least two storage cells (42-50') for storing electrical energy and a first connection unit

(10, 10', 20, 20', 30, 30') for electrically contacting the at least two storage cells (42-50'), in particular a connection unit (10, 10', 20, 20', 30, 30') according to any one of the preceding claims 1-8; and electrically connecting the at least two storage cells (42-50') to the first connection unit (10, 10', 20, 20', 30, 30').

12. Method for producing a second memory unit (40', 40"), in particular a second memory unit according to claim 10, comprising the steps:

providing a first memory unit (40), in particular a first memory unit according to claim 9;

Removing the first connection unit (10, 10', 20, 20', 30, 30') in such a way that at least one of the contact sections (14, 24, 34) of the first connection unit (10, 10', 20, 20', 30, 30') remains at least in sections on one of the storage cells (42-50'), the at least one remaining contact section preferably being separated from the connecting body (12, 22, 32) at the predetermined breaking point (16, 26, 36);

Contacting the storage cells (42-50') by means of a second connection unit (10, 10', 20, 20', 30, 30'), in particular a connection unit (10, 10', 20, 20', 30, 30'). one of the preceding claims 1-8, having at least two contact sections (14, 24, 34) which are designed for connection to the memory cells (42-50'); wherein the remaining contact portion (14, 24, 34) projects into the opening portion (28, 38, 39) and/or wherein at least one of the contact portions (14, 24, 34) of the second

connecting unit (10, 10', 20, 20', 30, 30') is connected to the remaining contact section (14, 24, 34), preferably by material bonding, in particular by welding.

13. The method according to the preceding claim 12, comprising the step: Replacing one, two or more of the memory cells (42-50') of the first memory unit (40).